M. Reffle
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Publication
Featured researches published by M. Reffle.
IEEE Journal of Selected Topics in Quantum Electronics | 2005
R. Nagarajan; Charles H. Joyner; R. Schneider; Jeffrey Bostak; T. Butrie; Andrew Dentai; Vincent G. Dominic; P. Evans; Masaki Kato; M. Kauffman; Damien Lambert; S.K. Mathis; Atul Mathur; R.H. Miles; Matthew L. Mitchell; Mark J. Missey; Sanjeev Murthy; Alan C. Nilsson; Frank H. Peters; S.C. Pennypacker; J. Pleumeekers; Randal A. Salvatore; R. Schlenker; Robert B. Taylor; Huan-Shang Tsai; M.F. Van Leeuwen; Jonas Webjorn; Mehrdad Ziari; Drew D. Perkins; J. Singh
We present an overview of Infineras current generation of 100 Gb/s transmitter and receiver PICs as well as results from the next-generation 500 Gb/s PM-QPSK PICs.
IEEE Journal of Selected Topics in Quantum Electronics | 2011
F. Kish; D. Welch; R. Nagarajan; J. Pleumeekers; Vikrant Lal; Mehrdad Ziari; Alan C. Nilsson; Masaki Kato; Sanjeev Murthy; P. Evans; Scott Corzine; Matthew L. Mitchell; Parmijit Samra; Mark J. Missey; Scott Demars; R. Schneider; M. Reffle; T. Butrie; Jeffrey T. Rahn; M.F. Van Leeuwen; J. W. Stewart; Damien Lambert; Ranjani Muthiah; Huan-Shang Tsai; Jeffrey Bostak; Andrew Dentai; Kuang-Tsan Wu; Han Sun; Don Pavinski; Jiaming Zhang
In this paper, the current state of the art for large-scale InP photonic integrated circuits (PICs) is reviewed with a focus on the devices and technologies that are driving the commercial scaling of highly integrated devices. Specifically, the performance, reliability, and manufacturability of commercial 100-Gb/s dense wavelength-division-multiplexed transmitter and receiver PICs are reviewed as well as next- and future-generation devices (500 Gb/s and beyond). The large-scale PIC enables significant reductions in cost, packaging complexity, size, fiber coupling, and power consumption which have enabled benefits at the component and system level.
optical fiber communication conference | 2011
Radhakrishnan Nagarajan; Damien Lambert; Masaki Kato; Vikrant Lal; Gilad Goldfarb; Jeff Rahn; Matthias Kuntz; Jacco Pleumeekers; Andrew Dentai; Huan-Shang Tsai; Roman Malendevich; Mark J. Missey; Kuang-Tsan Wu; Han Sun; John D. McNicol; Jie Tang; Jiaming Zhang; Tim Butrie; Alan C. Nilsson; M. Reffle; Fred A. Kish; D. O. Welch
A 10 channel, dual polarization, monolithically integrated, coherent QPSK receiver on InP operating at 100Gbit/s per channel is demonstrated.
optical fiber communication conference | 2011
P. Evans; M. Fisher; Roman Malendevich; Adam James; P. Studenkov; Gilad Goldfarb; T. Vallaitis; Masaki Kato; P. Samra; Scott Corzine; E. Strzelecka; Randal A. Salvatore; F. Sedgwick; Matthias Kuntz; Vikrant Lal; Damien Lambert; Andrew Dentai; Don Pavinski; Jiaming Zhang; Babak Behnia; Jeffrey Bostak; Vincent G. Dominic; Alan C. Nilsson; Brian Taylor; Jeffrey T. Rahn; Steve Sanders; Han Sun; Kuang-Tsan Wu; J. Pleumeekers; Ranjani Muthiah
A 10-wavelength, polarization-multiplexed, monolithically integrated InP transmitter PIC is demonstrated for the first time to operate at 112 Gb/s per wavelength with a coherent receiver PIC.
Semiconductor Science and Technology | 2012
Radhakrishnan Nagarajan; Masaki Kato; Damien Lambert; Peter Evans; Scott W. Corzine; Vikrant Lal; Jeffrey T. Rahn; Alan C. Nilsson; M. Fisher; Matthias Kuntz; Jacco Pleumeekers; Andrew Dentai; Huan-Shang Tsai; David J. Krause; Han Sun; Kuang-Tsan Wu; Mehrdad Ziari; Tim Butrie; M. Reffle; Matthew L. Mitchell; Fred A. Kish; D. O. Welch
In this paper, we review recent developments in the area of terabit/s?class monolithically integrated, transmitter and receiver photonic integrated circuits for the implementation of coherent, polarization-multiplexed, quadrature phase shift keying and higher order modulation formats.
Proceedings of the IEEE | 2013
Fred A. Kish; Radhakrishnan Nagarajan; David F. Welch; Peter Evans; Jon Rossi; J. Pleumeekers; Andrew Dentai; Masaki Kato; Scott Corzine; Ranjani Muthiah; Mehrdad Ziari; Richard P. Schneider; M. Reffle; Tim Butrie; Damien Lambert; Mark J. Missey; Vikrant Lal; M. Fisher; Sanjeev Murthy; Randal A. Salvatore; Scott Demars; Adam James; C. Joyner
The discovery of the visible light-emitting diode (LED) 50 years ago by Holonyak and Bevacqua and the associated demonstration of the viability of the III-V semiconductor alloy created a foundational basis for the field of optoelectronics. Key advances which enabled the progression from the first visible LED to todays III-V photonic integrated circuits (PICs) are described. Furthermore, the current state-of-the-art 500-Gb/s and 1-Tb/s large-scale InP transmitter and receiver PICs and their essential role in the optical communications networks are reviewed.
Optics Express | 2011
P. Evans; M. Fisher; Roman Malendevich; Adam James; Gilad Goldfarb; T. Vallaitis; Masaki Kato; P. Samra; Scott Corzine; E. Strzelecka; P. Studenkov; Randal A. Salvatore; F. Sedgwick; Matthias Kuntz; Lal; Damien Lambert; Andrew Dentai; Don Pavinski; Jiaming Zhang; Cornelius J; Tsai T; Babak Behnia; Jeffrey Bostak; Dominic; Alan C. Nilsson; Brian Taylor; Jeffrey T. Rahn; Steve Sanders; Han Sun; Kuang-Tsan Wu
In this work, a 10-wavelength, polarization-multiplexed, monolithically integrated InP coherent QPSK transmitter PIC is demonstrated to operate at 112 Gb/sec per wavelength and total chip superchannel bandwidth of 1.12 Tb/s. This demonstration suggests that increasing data capacity to multi-Tb/s per chip is possible and likely in the future.
optical fiber communication conference | 2008
Sanjeev Murthy; Masaki Kato; Radhakrishnan Nagarajan; Mark J. Missey; Vince Dominic; Vikrant Lai; Brian Taylor; Jacco Pleumeekers; Jianping Zhang; Peter Evans; Mehrdad Ziari; Ranjani Muthiah; Randal A. Salvatore; Huan-Shang Tsai; Alan Nilson; Don Pavinski; P. Studenkov; Shashank Agashe; Andrew Dentai; Damien Lambert; Jeffrey Bostak; J. Stewart; Charles H. Joyner; Jon Rossi; Richard P. Schneider; M. Reffle; Fred A. Kish; D. O. Welch
We have successfully demonstrated large-scale photonic integrated circuit (LS-PIC) transmitters with monolithically integrated semiconductor optical amplifiers. Data is presented for for 10 channel devices operating at 10 and 40 Gb/sec.
optical fiber communication conference | 2010
Radhakrishnan Nagarajan; Masaki Kato; Jacco Pleumeekers; Damien Lambert; Vikrant Lal; Andrew Dentai; Matthias Kuntz; Jeff Rahn; Huan-Shang Tsai; Roman Malendevich; Gilad Goldfarb; Jie Tang; Jiaming Zhang; Tim Butrie; Maura Raburn; Brent E. Little; Alan C. Nilsson; M. Reffle; Fred A. Kish; D. O. Welch
We demonstrate a 10 wavelength, monolithically integrated, polarization multiplexed, InP DQPSK receiver operating at 45.6 Gbit/s per wavelength.
lasers and electro optics society meeting | 2005
Charles H. Joyner; J. Pleumeekers; Atul Mathur; P. Evans; Damien Lambert; Sanjeev Murthy; S.K. Mathis; Frank H. Peters; J. Baeck; Mark J. Missey; Andrew Dentai; Randal A. Salvatore; R. Schneider; Mehrdad Ziari; Masaki Kato; R. Nagarajan; Jeffrey Bostak; T. Butrie; Vincent G. Dominic; M. Kauffman; R.H. Miles; Matthew L. Mitchell; Alan C. Nilsson; S.C. Pennypacker; R. Schlenker; Robert B. Taylor; Huan-Shang Tsai; M.F. Van Leeuwen; Jonas Webjorn; Drew D. Perkins
Commercial scaling of electronic integrated circuits has proceeded at a fast pace once the initial hurdle to integration was overcome. Recently, it has been shown that record active and passive optical device counts, exceeding 50 discrete components, can be incorporated onto a single monolithic 100 Gbps DWDM transmitter PIC InP chip. We will investigate key production metrics for this large-scale PIC commercial device as well as other analogs to other III-V semiconductor commercial devices. Using the yield management tools pioneered by silicon based electronics, we will present data supporting their scalability and the manufacturability of these large-scale PICs
